3 TGF-β: A Multipotential Cytokine

Stephen H. Schilling, A. Hjelmeland, J. Rich, Xiao-Fan Wang
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引用次数: 3

Abstract

Transforming growth factor-β (TGF-β) has been implicated as an important regulator of almost all major cell behaviors and activities, including proliferation, adhesion, motility, apoptosis, and differentiation. Which of these are affected and how they are regulated in response to TGF-β depend entirely on the cell type and the context in which the TGF-β signals are received. With such a large and diverse set of biological effects in such a wide range of cell types, it is not surprising that layers of regulation and cross-talk impinge on the TGF-β signaling pathway. This chapter provides a basic introduction to the molecular and biological responses controlled by TGF-β and how different levels of input help to regulate the specificity of these responses. Subsequent chapters discuss in greater depth the signaling mechanisms and different aspects of the cellular responses to TGF-β and TGF-β family proteins. TGF-β SIGNALS MEDIATE CHANGES IN GENE EXPRESSION To elicit gene expression responses, TGF-β uses a well-characterized signal transduction pathway that extends from the cell membrane to the nucleus (see Chapter 6). This signaling cascade is initiated when active TGF-β ligand binds to the TGF-β type II receptor (TβRII), which then forms a complex with the TGF-β type I receptor, known as TβRI or activin receptor–like kinase-5 (ALK-5). Formation of this activated ligand-bound receptor complex results in the phosphorylation of TβRI/ALK-5 by TβRII, thereby activating the type I receptor and permitting binding of Smad2 and/or Smad3. These receptor-activated Smads (R-Smads) are subsequently directly phosphorylated by TβRI/ALK-5 at the carboxyl...
TGF-β:一种多能细胞因子
转化生长因子-β (TGF-β)被认为是几乎所有主要细胞行为和活动的重要调节因子,包括增殖、粘附、运动、凋亡和分化。在TGF-β的作用下,其中哪些受到影响,以及它们如何受到调节,完全取决于细胞类型和TGF-β信号被接收的环境。由于在如此广泛的细胞类型中存在如此大量和多样的生物效应,因此TGF-β信号通路受到多层调控和串扰的影响也就不足为奇了。本章基本介绍了TGF-β调控的分子生物学反应,以及不同水平的输入如何调控这些反应的特异性。随后的章节将更深入地讨论细胞对TGF-β和TGF-β家族蛋白反应的信号机制和不同方面。TGF-β信号介导基因表达变化为了引起基因表达反应,TGF-β使用了一条特征明确的信号转导途径,从细胞膜延伸到细胞核(见第6章)。当活性TGF-β配体与TGF-β II型受体(t -β rii)结合时,该信号级联开始,然后与TGF-β I型受体(称为t -β ri或激活素受体样激酶-5 (ALK-5))形成复合物。这种活化的配体结合受体复合物的形成导致TβRII磷酸化TβRI/ALK-5,从而激活I型受体并允许Smad2和/或Smad3结合。这些受体激活的Smads (R-Smads)随后被t - β ri /ALK-5在羧基上直接磷酸化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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